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mechanisms of virus self-assembly. RNA-containing viruses are complex, nanometre sized particles with at their centre proteins covering the RNA. We want to find out how these complex assemblies are built up
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. The main objective of this project is to unravel the molecular mechanisms of virus self-assembly. RNA-containing viruses are complex, nanometre sized particles with at their centre proteins covering the RNA
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mechanisms of virus self-assembly. RNA-containing viruses are complex, nanometre sized particles with at their centre proteins covering the RNA. We want to find out how these complex assemblies are built up
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on accurate constitutive models that describe the behavior of the molten material during forming. With the increasing demand for more complex components, a step change in model accuracy and associated material
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that can self-learn bulk visco-elastic properties? How to structure such materials to learn continually and counteract the aging of their own parts? Can we optimize self-learning materials to achieve
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the increasing demand for more complex components, a step change in model accuracy and associated material characterization methods is required. For this purpose, we are looking for two PhD candidates to tackle
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requirements in conflict zones and other industrial contexts; investigate optimal levels within the product structure for deploying AM in repair and spare parts support; integrate forward and reverse flows in
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for the aforementioned complexities. In this project, you will: Develop and implement a multiscale – both spatial and temporal – numerical framework that enables efficient LAFP process simulations of large structures
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computational model to capture the complex transport of gases, liquids, and charges in these porous structures, including the complex interfaces between them. Insights from the model will directly guide the
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analyze complex eye-tracking and donated social media data, recruit participants for all studies); Write academic articles for publication in high-impact scientific journals, and present findings at (inter